DE202017102702U1 - secondary battery - Google Patents

Abstract

A secondary battery (2) comprising: at least one first metal plate (20) used as a positive terminal; at least one second metal plate (21) used as a negative terminal; a separator material (22) provided between the at least one first metal plate (20) and the at least one second metal plate (21) to form a positive contact material on the at least one first metal plate (20) of a negative contact material on the at least one second one To keep metal plate (21) separated; a liquid electrolyte (23); and an integrated circuit (24) for controlling a wireless connection of the RFID, WIFI, NFC, Bluetooth or SRI, wherein on the at least one first metal plate (20) and / or on the at least one second metal plate (21) a coil pattern (25 ) composed of an antenna coil pattern, a charge and discharge coil pattern for electromagnetic induction or electric field induction, an antenna antenna coil pattern, a charge and discharge coil pattern for audio wave induction, and a charge and discharge coil Discharge coil pattern for the X-ray induction or for the laser light induction is selected to transfer energy between the positive terminal and the negative terminal, this energy transfer is controlled by the integrated circuit (24).

Description

BACKGROUND OF THE INVENTION

Technical area

The present invention relates to a secondary battery.

State of the art

At present, a variety of secondary batteries are available that differ in their capacities and performances because of the materials that make them up. The inventor of the present invention proposes a secondary battery which surpasses those of the prior art secondary batteries in both capacity and power.

OBJECT OF THE INVENTION

The object of the present invention is to provide a secondary battery.

According to an embodiment of the present invention, a secondary battery is composed of the following components: at least a first metal plate used as a positive terminal; at least one second metal plate used as a negative terminal; a separator material between the at least one first metal plate and the at least one second metal plate, with which a positive contact material on the at least one first metal plate is kept separate from a negative contact material on the at least one second metal plate; a liquid electrolyte; and an integrated circuit for controlling a wireless connection of the RFID, WIFI, NFC, Bluetooth or SRI, wherein on the at least one first metal plate and / or on the at least one second metal plate, a coil pattern is formed, which consists of a group of antenna coil pattern , an electromagnetic induction or electric field induction charging and discharging coil pattern, an antenna antenna coil pattern, a charge and discharge coil pattern for audio wave induction, and a charge and discharge coil pattern for X-ray induction or the laser light induction is selected to transfer the energy between the positive terminal and the negative terminal and this energy transfer is thereby controlled by the integrated circuit.

BRIEF DESCRIPTION OF THE DRAWINGS

1 shows an enlarged view of a part of a secondary battery according to a first embodiment of the present invention.

2 Fig. 11 is an illustrative view of a metal plate and a coil pattern of a secondary battery of the present invention.

3 Fig. 11 shows another illustrative view of a metal plate and a coil pattern of a secondary battery of the present invention.

4 Fig. 11 is an illustrative view of a metal plate and a Tesla coil of a secondary battery of the present invention.

5 (a) shows a secondary battery without separator material according to an embodiment of the present invention, and the 5 (b) shows a secondary battery with a separator material according to an embodiment of the present invention.

6 (a) FIG. 12 shows a first (or second) metal plate of the present invention having a 1D structure (a deposition layer). FIG 6 (b) shows a first (or second) metal plate of the present invention having a 2D structure (two deposition layers), and FIGS 6 (c) shows a first (or second) metal plate of the present invention having a 3D structure (three deposition layers).

7 Fig. 11 is an illustrative view of a parallel connection structure for charging a secondary battery and a series connection structure for discharging the secondary battery according to an embodiment of the present invention.

8th shows an illustrative view of a secondary battery according to an embodiment of the present invention.

9 shows an illustrative view of a secondary battery according to another embodiment of the present invention.

10 shows an illustrative view of a secondary battery according to another embodiment of the present invention.

11 Fig. 11 is an exploded view of an apparatus using a secondary battery of the present invention.

12 shows an illustrative view of a secondary battery according to yet another embodiment of the present invention.

WAYS TO CARRY OUT THE PREFERRED EMBODIMENTS

In the detailed descriptions below of the preferred embodiments, the same or similar elements that are used with the same reference numerals are omitted, as well as redundant descriptions omitted. To clearly illustrate the characteristics of the present invention, the elements in the drawings are not reproduced to scale.

The 1 shows an enlarged view of a part of a secondary battery 2 according to a first embodiment of the present invention. Like in the 1 shown, is the secondary battery 2 from at least one first metal plate 20 which is used as a positive terminal, at least one second metal plate 21 , which is used as a negative terminal, and a separator material 22 between the at least one first metal plate 20 and the at least one second metal plate 21 is provided to a layer of material 200 the positive terminal, with which the at least one first metal plate 20 is coated from a layer of material 210 the negative terminal, with which the at least one second metal plate 21 coated to keep it separate. It should be noted that the secondary battery 2 further consists of a housing with the dashed line in the 7 is shown, wherein the at least one first metal plate 20 that has at least one second metal plate 21 and the separator material 22 folded and received in this case.

In this embodiment and with reference to FIGS 2 . 3 and 8th consists of the secondary battery 2 within the housing further from a liquid electrolyte 23 and from an integrated circuit 24 which controls a wireless connection of RFID (Radio Frequency Identification), WIFI, NFC (Near Field Communication), Bluetooth or SRI (Near-Field Radio). Next is on the at least one first metal plate 20 and / or on the at least one second metal plate 21 a coil pattern 25 formed with the integrated circuit 24 connected and as an antenna coil pattern 25 , a charge and discharge coil pattern 25 for the electromagnetic induction or for the induction of the electric field, an acoustic antenna coil pattern 25 , a charge and discharge coil pattern 25 for audio wave induction and as a charge and discharge coil pattern 25 for X-ray induction or for laser light induction, to transfer energy between the positive terminal and the negative terminal. With the integrated circuit 24 this energy transfer is controlled. The 2 . 3 and 8th also show that the coil pattern may have a different shape.

The 4 and 9 show deviating from those in the 2 and in the 3 shown embodiments that on the at least one first metal plate 20 and / or on the at least one second metal plate 21 a Tesla coil 25 is formed, wherein the integrated circuit 24 is omitted. This Tesla coil 25 generates a charging current for the at least one first metal plate 20 with the help of electromagnetic induction or the induction of the electric field.

5 (a) differs from the first preferred embodiment shows that the separator material and the liquid electrolyte are omitted, wherein the secondary battery of an ionic crosslinking material 26 within both the material layer 200 the positive terminal on the at least one first metal plate 20 as well as the material layer 210 the negative terminal on the at least one second metal plate 21 consists. The 5 (b) shows, however, that the secondary battery with the separator material and the liquid electrolyte installed is also made of the ionic crosslinking material 26 within both the positive contact material 200 on the at least one first metal plate 20 as well as the negative contact material 210 on the at least one second metal plate 21 can exist.

The 6 (a) - 6 (c) shows the variants of the embodiments of the at least one first metal plate 20 and the at least one second metal plate 21 the secondary battery of the present invention. The 6 (a) shows that the metal plate 20 ( 21 ) a layer of material 200 ( 210 ) has the positive (negative) terminal coated on both of its opposite surfaces to form a 1D structure (a deposition layer). The 6 (b) shows that the metal plate 20 ( 21 ) two layers of material 200 ( 210 ) of the positive (negative) clamp with which both of its opposite surfaces are coated to form a 2D structure (two deposition layers). The 6 (c) shows that the metal plate 20 ( 21 ) three layers of material 200 ( 210 ) of the positive (negative) clamp with which both of its opposite surfaces are coated to form a 3D structure (three deposition layers). Its capacitance formula can be expressed as C = ε (A / d), where C is a capacitance value, ε is a dielectric constant, A is an overlap area of the two parallel plates, and d is a separation between the two parallel plates, simplified to C = A and ε = d = 1, therefore, the current density of the secondary battery can be reduced by increasing the surface area of the material layers of the positive (negative) terminal, and thereby the energy density of the secondary battery can be significantly improved. Further, the ionic crosslinking material 26 used with a conductive metal material or a conductive non-metal material in the form of particles and with UV adhesive (ultraviolet), PVDF (polyvinylidene fluoride), CMC (carboxymethylcellulose), SBR Adhesive (styrene-butadiene rubber) or be enclosed with liposomes to increase the surface area of the material layers of the positive (negative) terminal and thus to improve the current density of the secondary battery.

The 7 shows an illustrative view of a secondary battery according to another embodiment of the present invention. Like in the 7 shown are the first metal plate 20 and the second metal plate 21 in a housing (marked with a dashed line) folded and picked up. In contrast to the previous embodiment comes in this embodiment, a secondary battery with a first diode 27 and with a second diode 28 for application, the first metal plate 20 from four electrode contacts 200 consists. The first diode 27 has an N-terminal (cathode) that connects to three of the four electrode contacts 200 and a P-terminal (anode), this P-terminal being used as an input terminal so that an input current Iin can be divided into three sub-currents as represented by Iin = I1 + I2 + I3, where I1, I2 and I3 are respective secondary currents. The second diode 28 has an N-terminal (cathode) connected to the P-terminal of the first diode 27 while a P-clamp (anode) is connected to the remaining four electrode contacts 200 is connected to produce an output current Iout = I1 = I2 = I3, which has a single sidestream. With this arrangement, the secondary battery can be charged via the parallel current paths and discharged via a series current path.

The 10 shows an illustrative view of a secondary battery according to another embodiment of the present invention. Unlike the ones in the 8th and in the 9 In this embodiment, a secondary battery with a flywheel generator is shown 30 for use. This flywheel generator 30 that consists of several coils 300 and magnetic poles 301 can exist on the first metal plate 20 and / or on the second metal plate 21 be formed around the flywheel generator 30 for supplying a charging current to the first metal plate 20 to activate when a charge current flows in the secondary battery or when the flywheel generator 30 an external electromagnetic induction is exposed.

The 11 Fig. 11 is an exploded view of an apparatus using a secondary battery of the present invention. Like in the 11 shown is the secondary battery 2 installed in a protective housing of a cell phone, so that the secondary battery 2 when inserting the phone in its protective housing is electrically connected to a mobile phone and can be activated to charge the phone when needed. It should be noted that the application of the secondary battery of the present invention does not apply to those described in U.S.P. 11 shown device is limited. Actually, the secondary battery 2 of the present invention can be applied to any apparatus in which a secondary battery is required, including, but not limited to, electric cars, electric motorcycles, notebook computers, tablet computers, cell phones, robots, etc.

The 12 shows an illustrative view of a secondary battery according to yet another embodiment of the present invention. In this embodiment, the secondary battery 2 continue from a contact 40 the positive terminal, which protrudes from the housing (indicated by dashed lines) and from a contact 41 the negative terminal that sticks out of the housing to an external circuit (not shown) and a pair of fuses 42 connect to. One of the pair of fuses 42 is electrically between the contact 40 the positive terminal and the first metal plate 20 and the other of the pair of fuses 42 is electrically between the contact 41 the negative terminal and the second metal plate 21 connected. The fuse 42 can be used with an adhesive doped with highly conductive metal particles, which adhesive has a higher thermal expansion coefficient than the highly conductive metal particles. If an ambient temperature is higher than a pre-set threshold, the adhesive expands significantly more than the highly conductive metal particles, leaving the pair with fuses 42 the electrical conductivity loses, otherwise an electrical connection between the contact 40 the positive terminal and the first metal plate 20 and an electrical connection between the contact 41 the negative terminal and the second metal plate 21 interrupts. When the ambient temperature is cooled to below the threshold, the initial state of the adhesive and the highly conductive metal particles is restored to the electrical connection between the contact 40 the positive terminal and the first metal plate 20 and the electrical connection between the contact 41 the negative terminal and the second metal plate 21 restore. The preset threshold can be any temperature between 20 ° C and 200 ° C.

It should be noted that the fuse 42 can also be used with two metals with different coefficients of thermal expansion in contact with each other, so that the fuse 42 becomes non-conductive when an ambient temperature exceeds a preset threshold, so that the two metals are expanded differently and therefore both metals are no longer in contact with each other, the fuse 42 can become conductive when the ambient temperature is cooled below the preset threshold to restore the initial state of the metals and bring these metals back into contact with each other.

In conclusion, with the above-described structures and the devices having the secondary battery of the present invention, the objectives are achieved, the expected functions are fulfilled, and the desired results are achieved. In addition, to the knowledge of the Applicant, since the present invention is not found in any publications and is not used in public, the present invention meets all the requirements for filing patent protection.

In spite of the description of the present invention by way of example and preferred embodiments, it is to be understood that the present invention should not be so limited. Rather, the present invention is also intended to cover various modifications and similar arrangements and acts, the scope of the appended claims being fully intended to cover all modifications and similar arrangements and acts.

Claims (14)

A secondary battery ( 2 ), comprising: at least one first metal plate ( 20 ) used as a positive terminal; at least one second metal plate ( 21 ), which is used as a negative terminal; a separator material ( 22 ), which between the at least one first metal plate ( 20 ) and the at least one second metal plate ( 21 ) is provided to a positive contact material on the at least one first metal plate ( 20 ) of a negative contact material on the at least one second metal plate ( 21 ) keep separate; a liquid electrolyte ( 23 ); and an integrated circuit ( 24 ) for controlling a wireless connection of the RFID, WIFI, NFC, Bluetooth or SRI, wherein on the at least one first metal plate ( 20 ) and / or on the at least one second metal plate ( 21 ) a coil pattern ( 25 ) composed of an antenna coil pattern, a charge and discharge coil pattern for electromagnetic induction or electric field induction, an antenna antenna coil pattern, a charge and discharge coil pattern for audio wave induction, and a charge and discharge coil Discharge coil pattern for the X-ray induction or for the laser light induction is selected to transfer energy between the positive terminal and the negative terminal, this energy transfer with the integrated circuit ( 24 ) is controlled. A secondary battery ( 2 ), comprising: at least one first metal plate ( 20 ) used as a positive terminal; at least one second metal plate ( 21 ), which is used as a negative terminal; an ionic crosslinking material ( 26 formed as conductive metal particles or conductive non-metal particles and enclosed with a UV adhesive, PVDF adhesive, CMC adhesive, SBR adhesive or with liposomes and in a material layer of the positive terminal on the at least one first metal plate and in a material layer of negative terminal of the at least one second metal plate is provided; and an integrated circuit ( 24 ) for controlling a wireless connection of the RFID, WIFI, NFC, Bluetooth or SRI, wherein on the at least one first metal plate ( 20 ) and / or on the at least one second metal plate ( 21 ) a coil pattern ( 25 ) composed of an antenna coil pattern, a charge and discharge coil pattern for electromagnetic induction or electric field induction, an antenna antenna coil pattern, a charge and discharge coil pattern for audio wave induction, and a charge and discharge coil Discharge coil pattern for the X-ray induction or for the laser light induction is selected to transfer energy between the positive terminal and the negative terminal, this energy transfer with the integrated circuit ( 24 ) is controlled. A secondary battery ( 2 ), comprising: at least one first metal plate ( 20 each having a surface coated with at least one layer of positive contact material to form a single-layer or multi-layer positive terminal, said positive contact material consisting of particles of a conductive metal material or conductive non-metal material comprised of a UV adhesive , PVDF adhesive, CMC adhesive, SBR adhesive or are enclosed by liposomes in order to increase a surface area of the positive contact material and thus a current density of the secondary battery ( 2 ) increase; at least one second metal plate ( 21 each having a surface coated with at least one layer of a negative contact material to form a single-layer or multi-layer negative terminal, wherein the negative contact material is composed of particles of a conductive metal material or a conductive non-metal material that is UV-adhesive , PVDF adhesive or are enclosed by liposomes to increase a surface area of the negative contact material and thus a current density of the secondary battery ( 2 ) increase; a separator material ( 22 ), which between the at least one first metal plate ( 20 ) and the at least one second metal plate ( 21 ) is provided to the positive contact material on the at least one first metal plate ( 20 ) of the negative contact material on the at least one second metal plate ( 21 ) keep separate; and a liquid electrolyte ( 23 ), wherein the single-layered or multi-layered positive terminal and the single-layered or multi-layered negative terminal are provided to enlarge a surface area of the positive contact material and the negative contact material so that the secondary battery ( 2 ) achieves a higher current density and thus their energy density is improved. A secondary battery ( 2 ), comprising: at least one first metal plate ( 20 each having a surface coated with at least one layer of positive contact material to form a single-layer or multi-layer positive terminal, said positive contact material consisting of particles of a conductive metal material or conductive non-metal material comprised of a UV adhesive , PVDF adhesive, CMC adhesive, SBR adhesive or are enclosed by liposomes to increase a surface area of the positive contact material and thus a current density of the secondary battery ( 2 ) increase; at least one second metal plate ( 21 each having a surface coated with at least one layer of a negative contact material to form a single-layer or multi-layer negative terminal, wherein the negative contact material is composed of particles of a conductive metal material or a conductive non-metal material that is UV-adhesive , PVDF adhesive or are enclosed by liposomes to increase a surface area of the negative contact material and thus a current density of the secondary battery ( 2 ) increase; and an ionic crosslinking material ( 26 formed as conductive metal particles or conductive non-metal particles and enclosed by a UV adhesive, PVDF adhesive, CMC adhesive, SBR adhesive or liposomes and in both the positive contact material on the at least one first metal plate ( 20 ) as well as in the negative contact material on the at least one second metal plate ( 21 ) is provided; wherein the single-layered or multi-layered positive terminal and the single-layered or multi-layered negative terminal provide larger surface areas of the positive contact material and the negative contact material, so that the secondary battery ( 2 ) has an increased current density and therefore improves their energy density. A secondary battery ( 2 ), comprising: at least one first metal plate ( 20 ) coated with a positive contact material and used as a positive terminal, the at least one first metal plate having N electrode contacts and wherein N is a positive integer; at least one second metal plate ( 21 ) is coated with a negative contact material and used as a negative terminal; a separator material ( 22 ), which between the at least one first metal plate ( 20 ) and the at least one second metal plate ( 21 ) is provided to the positive contact material on the at least one first metal plate ( 20 ) of the negative contact material on the at least one second metal plate ( 21 ) keep separate; a liquid electrolyte ( 23 ); a first diode ( 27 ) with an N-terminal connected in parallel with N-1 electrode contacts of the N-electrode contacts, while a P-terminal is used as an input terminal, so that an input current I _in with I _in = I ₁ + I ₂ + I ₃ + ... + I _N-1 , where I ₁ , I ₂ , I ₃ , ..., I are _N-1 tributaries corresponding to the N-1 contacts; and a second diode ( 28 ) with an N-terminal connected to the P-terminal of the first diode ( 27 ), while a P-terminal connected to the N-th electrode contact of the N electrode contacts, so that an output current I _out corresponds to a side current I _N , wherein with the secondary battery ( 2 ) parallel power paths for a charging process and a serial power path for a discharge process are created. A secondary battery ( 2 ), comprising: at least one first metal plate ( 20 ), which is coated with a positive contact material and used as a positive terminal, while the at least one first metal plate ( 20 ) N has electrode contacts and N is a positive integer; at least one second metal plate ( 21 ) is coated with a negative contact material and used as a negative terminal; an ionic crosslinking material ( 26 formed as conductive metal particles or as conductive non-metal particles and enclosed by a UV adhesive, PVDF adhesive, CMC adhesive, SBR adhesive or liposomes, wherein they are in both the positive contact material on the at least one first metal plate ( 20 ) as well as in the negative contact material on the at least one second metal plate ( 21 ) are provided; a first diode ( 27 ) with an N-terminal connected to the N-1 electrode contacts of the N Electrode contacts are connected in parallel, while a P-terminal is used as an input terminal, so that an input current I _{in is represented} by I _in = I ₁ + I ₂ + I ₃ + ... + I _N-1 , where I ₁ , I ₂ , I ₃ , ..., I _N-1 are tributaries corresponding to the N-1 contacts; and a second diode ( 28 ) with an N-terminal connected to the P-terminal of the first diode, while a P-terminal is connected to the N-th electrode contact of the N electrode contacts, so that an output current I _out corresponds to a side current I _N , where the secondary battery ( 2 ) Parallel current paths for charging and series current paths are created for a discharge. A secondary battery ( 2 ), comprising: at least one first metal plate ( 20 ) used as a positive terminal; at least one second metal plate ( 21 ), which is used as a negative terminal; a separator material ( 22 ), which between the at least one first metal plate ( 20 ) and the at least one second metal plate ( 21 ) is provided to a positive contact material on the at least one first metal plate ( 20 ) of a negative contact material on the at least one second metal plate ( 21 ) keep separate; a liquid electrolyte ( 23 ); and a flywheel generator ( 30 ) with several coils ( 300 ) and magnetic poles, so that the flywheel generator ( 30 ) can be activated in order to charge a charging current to the at least one first metal plate ( 20 ), when a charging current in the secondary battery ( 2 ) or when the flywheel generator ( 30 ) is exposed to external electromagnetic induction. A secondary battery ( 2 ), comprising: at least one first metal plate ( 20 ) used as a positive terminal; at least one second metal plate ( 21 ), which is used as a negative terminal; an ionic crosslinking material ( 26 formed as conductive metal particles or as conductive non-metal particles and enclosed by a UV adhesive, PVDF adhesive, CMC adhesive, SBR adhesive or liposomes and in both a positive contact material on the first metal plate ( 20 ) as well as in a negative contact material on the at least one second metal plate ( 21 ) is provided; and a flywheel generator ( 30 ) with several coils ( 300 ) and magnetic poles, so that the flywheel generator ( 30 ) can be activated to a load current to the at least one first metal plate ( 20 ), when a charging current in the secondary battery ( 2 ) or when the secondary battery ( 2 ) is exposed to external electromagnetic induction. A secondary battery ( 2 ), comprising: at least one first metal plate ( 20 ) used as a positive terminal; at least one second metal plate ( 21 ), which is used as a negative terminal; a separator material ( 22 ), which between the at least one first metal plate ( 20 ) and the at least one second metal plate ( 21 ) is provided to a positive contact material on the at least one first metal plate ( 20 ) of a negative contact material on the at least one second metal plate ( 21 ) keep separate; a liquid electrolyte ( 23 ); and a Tesla coil ( 25 ) for generating a charging current for the at least one first metal plate ( 20 ) by the electromagnetic induction or by the induction of the electric field. A secondary battery ( 2 ), comprising: at least one first metal plate ( 20 ) used as a positive terminal; at least one second metal plate ( 21 ), which is used as a negative terminal; an ionic crosslinking material ( 26 formed as conductive metal particles or as conductive non-metal particles and enclosed by a UV adhesive, PVDF adhesive, CMC adhesive, SBR adhesive or liposomes and in both a positive contact material on the at least one first metal plate ( 20 ) as well as in a negative contact material on the at least one second metal plate ( 21 ) is available; and a Tesla coil ( 25 ) for generating a load current for the at least one first metal plate ( 20 ) by the electromagnetic induction or by the induction of the electric field. A secondary battery ( 2 ), comprising: at least one first metal plate ( 20 ) used as a positive terminal; at least one second metal plate ( 21 ), which is used as a negative terminal; a separator material ( 22 ), which between the at least one first metal plate ( 20 ) and the at least one second metal plate ( 21 ) is provided to a positive contact material on the at least one first metal plate ( 20 ) of a negative contact material on the at least one second metal plate ( 21 ) keep separate; a liquid electrolyte ( 23 ); a contact ( 40 ) the positive terminal for electrical connection to an external circuit; a contact ( 41 ) the negative terminal for electrical connection to the external circuit; and a pair of fuses ( 42 ), one of the pair Fuses ( 42 ) electrically between the contact ( 40 ) of the positive terminal and the at least one first metal plate ( 20 ), while the other of the pair of fuses ( 42 ) electrically between the contact ( 41 ) of the negative terminal and the at least one second metal plate ( 21 ), the pair of fuses ( 42 ) is used with an adhesive material and this adhesive material is doped with highly conductive metal particles, which adhesive material has a higher coefficient of thermal expansion than the highly conductive metal particles, wherein when an ambient temperature is higher than a preset threshold, the adhesive material is extended far more than that highly conductive metal particles, thereby making the pair of fuses ( 42 ) loses the electrical conductivity with which an electrical connection between the contact ( 40 ) of the positive terminal and the at least one first metal plate ( 20 ) and an electrical connection between the contact ( 41 ) of the negative terminal and the at least one second metal plate ( 21 ), wherein upon cooling of the ambient temperature to below the preset threshold, the initial state of the adhesive material and the highly conductive metal particles is restored to the electrical connection between the contact ( 40 ) of the positive terminal and the at least one first metal plate ( 20 ) and the electrical connection between the contact ( 41 ) of the negative terminal and the at least one second metal plate ( 21 ) restore. A secondary battery ( 2 ), comprising: at least one first metal plate ( 20 ) used as a positive terminal; at least one second metal plate ( 21 ), which is used as a negative terminal; an ionic crosslinking material ( 26 formed as conductive metal particles or as conductive non-metal particles and enclosed by a UV adhesive, PVDF adhesive, CMC adhesive, SBR adhesive or liposomes and in both a positive contact material on the at least one first metal plate ( 20 ) as well as in a negative contact material on the at least one second metal plate ( 21 ) is provided; a contact ( 40 ) the positive terminal for electrical connection to an external circuit; a contact ( 41 ) the negative terminal for electrical connection to the external circuit; and a pair of fuses ( 42 ), one of these pairs being fuses ( 42 ) electrically between the contact ( 40 ) of the positive terminal and the at least one first metal plate ( 20 ) and one of the pairs of fuses ( 42 ) electrically between the contact ( 41 ) of the negative terminal and the at least one second metal plate ( 21 ), the pair of fuses ( 42 ) is used with an adhesive material and this adhesive material is doped with highly conductive metal particles, which adhesive material has a higher coefficient of thermal expansion than the highly conductive metal particles, wherein when an ambient temperature is higher than a preset threshold, the adhesive material is extended far more than that highly conductive metal particles, thereby making the pair of fuses ( 42 ) loses the electrical conductivity with which an electrical connection between the contact ( 40 ) of the positive terminal and the at least one first metal plate ( 20 ) and an electrical connection between the contact ( 41 ) of the negative terminal and the at least one second metal plate ( 21 ), wherein upon cooling of the ambient temperature to below the preset threshold, the initial state of the adhesive material and the highly conductive metal particles is restored to the electrical connection between the contact ( 40 ) of the positive terminal and the at least one first metal plate ( 20 ) and the electrical connection between the contact ( 41 ) of the negative terminal and the at least one second metal plate ( 21 ) restore. A secondary battery ( 2 ), comprising: at least one first metal plate ( 20 ) used as a positive terminal; at least one second metal plate ( 21 ), which is used as a negative terminal; a separator material ( 22 ), which between the at least one first metal plate ( 20 ) and the at least one second metal plate ( 21 ) is provided to a positive contact material on the at least one first metal plate ( 20 ) of a negative contact material on the at least one second metal plate ( 21 ) keep separate; a liquid electrolyte ( 23 ); a contact ( 40 ) the positive terminal for electrical connection to an external circuit; a contact ( 41 ) the negative terminal for electrical connection to an external circuit; and a pair of fuses ( 42 ), whereby one of the pairs of fuses ( 42 ) electrically between the contact ( 40 ) of the positive terminal and the at least one first metal plate ( 20 ), while the other of the pairs fuses ( 42 ) electrically between the contact ( 41 ) of the negative terminal and the at least one second metal plate ( 21 ), the pair of fuses ( 42 ) with two metals with different thermal expansion coefficients are in contact with each other, so that the pair of fuses ( 42 ) becomes non-conductive when an ambient temperature is higher than a preset threshold, the two metals extending differently to an extent where the two metals are no longer in contact with each other, and wherein the pair of fuses ( 42 ) again becomes conductive when the ambient temperature is below the preset threshold is cooled to bring the two metals back into contact with each other. A secondary battery ( 2 ), comprising: at least one first metal plate ( 20 ) used as a positive terminal; at least one second metal plate ( 21 ), which is used as a negative terminal; an ionic crosslinking material ( 26 formed as conductive metal particles or as conductive non-metal particles and enclosed by a UV adhesive, PVDF adhesive, CMC adhesive, SBR adhesive or liposomes and in both a positive contact material on the at least one first metal plate ( 20 ) as well as in a negative contact material on the at least one second metal plate ( 21 ) is provided; a contact ( 40 ) the positive terminal for electrical connection to an external circuit; a contact ( 41 ) the negative terminal for electrical connection to an external circuit; and a pair of fuses ( 42 ), one of the pair of fuses ( 42 ) electrically between the contact ( 40 ) of the positive terminal and the at least one first metal plate ( 20 ), while the other of the pair of fuses ( 42 ) electrically between the contact ( 41 ) of the negative terminal and the at least one second metal plate ( 21 ), the pair of fuses ( 42 ) with two metals with different thermal expansion coefficients are in contact with each other, so that the pair of fuses ( 42 ) becomes nonconductive when an ambient temperature is higher than a preset threshold, the two metals extending differently to an extent where the two metals are no longer in contact with each other; the pair of fuses ( 42 ) again becomes conductive when the ambient temperature is cooled below the preset threshold to re-contact the two metals.

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